In a semiconductor integrated circuit device, arrangement relationship of power source area i/O pads differs between a peripheral portion and a center portion of a gate region of a chip. That is, in two columns and two rows of the peripheral portion of the gate region, VDD area i/O pads connected to a high-voltage power source VDD and GND area i/O pads connected to a ground power source GND are alternately aligned and arranged both in a row direction and in a column direction. Moreover, in the center portion of the gate region, the same VDD area i/O pads or the same GND area i/O pads are successively aligned in the row direction, and the VDD area i/O pads and the GND area i/O pads are alternately aligned and arranged in the column direction.
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1. A semiconductor integrated circuit device comprising:
a peripheral i/O region in which i/O cells are arranged;
a gate region surrounded by the peripheral i/O region;
a plurality of power area pads arranged in the gate region; and
first and second power source lines, wherein:
the plurality of power area pads are arranged in a matrix along a raw direction and a column direction, and include first power area pads connected to the first power source line and second power area pads connected to the second power source line,
the gate region comprises a peripheral portion and a center portion, the peripheral portion being adjacent to the peripheral i/O region and the center portion being not adjacent to the peripheral i/O region,
the plurality of power area pads in the peripheral portion is arranged such that the first power area pads and the second power area pads are alternately disposed in a direction of a boundary between the peripheral i/O region and the peripheral portion of the gate region, and
the plurality of power area pads in the center portion include at least one row or column that includes either (i) only the first power area pads or (ii) only the second power area pads, as the power area pads.
2. The semiconductor integrated circuit device of
the first power area pads connected to the first power source line and the second power area pads connected to the second power source line are alternately arranged, in at least two rows or two columns, both in the row direction and in the column direction in the peripheral portion of the gate region.
3. The semiconductor integrated circuit device of
the first power source line is connected to a high-voltage power source, and
the second power source line is connected to a ground power source.
4. The semiconductor integrated circuit device of
the second power area pads are composed of first-second power area pads connected to the second power source line and second-second power area pads connected to a third power source line, and
the plurality of power area pads in the center portion include at least one row or column that includes either (a) only the first power area pads, (b) only the first-second power area pads or (c) only the second-second power area pads, as the power area pads.
5. The semiconductor integrated circuit device of
6. The semiconductor integrated circuit device of
a plurality of peripheral i/O pads arranged in the peripheral i/O region.
7. The semiconductor integrated circuit device of
a plurality of signal pads disposed between the plurality of power area pads.
8. The semiconductor integrated circuit device of
the first power area pads connected to the first power source line and the second power area pads connected to the second power source line are alternately arranged, in at least two rows or two columns, both in the row direction and in the column direction in the peripheral portion of the gate region.
9. The semiconductor integrated circuit device of
the first power source line is connected to a high-voltage power source, and
the second power source line is connected to a ground power source.
10. The semiconductor integrated circuit device of
a plurality of peripheral i/O pads arranged in the peripheral i/O region.
11. The semiconductor integrated circuit device of
a plurality of signal pads disposed between the plurality of power area pads.
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This is a continuation of PCT International Application PCT/JP2010/001101 filed on Feb. 19, 2010, which claims priority to Japanese Patent Application No. 2009-049030 filed on Mar. 3, 2009, and to PCT International Application PCT/JP2009/003383 filed on Jul. 17, 2009. The disclosures of these applications including the specifications, the drawings, and the claims are hereby incorporated by reference in their entirety.
The disclosure relates to semiconductor integrated circuit devices including area I/O pads laid out in a flip chip having multilayer interconnect layers and power source structures of the flip chip.
To design semiconductor integrated circuits, positions of peripheral I/O regions in which I/O cells are arranged and positions of gate regions in which standard cells or macros are arranged are predetermined. For example, the peripheral I/O regions are peripheral portions of chips serving as semiconductor integrated circuit devices, and the gate regions are center portions (inner portions) surrounded by the peripheral I/O regions. When the semiconductor integrated circuits are designed, the I/O cells, the standard cells, and the macros are designed and arranged in the inner portions of the predetermined peripheral I/O regions and the predetermined gate regions.
Moreover, the I/O cells and the ESD protection circuits are connected to I/O pads each of which is connected to signals input/output to/from the chip 200 or a power source. The I/O pads connected to the power sources are hereinafter referred to as power source I/O pads. The I/O pads connected to the signals are hereinafter referred to as signal I/O pads. When it is not particularly necessary to distinguish the power source I/O pads from the signal I/O pads, they are simply referred to as I/O pads.
Conventionally, the I/O pads are arranged in the peripheral I/O region. In the semiconductor integrated circuit device including such I/O pads, the number of I/O pads increases as the number of signals input/output to/from the chip 200 increases, so that it is necessary to increase the length of chip sides. Here, since the area of the gate region increases as the length of the chip sides increases, there is a concern that dead space in the gate region may increase depending on the gate size. Moreover, when the length of the chip sides increases, the distance from the power source I/O pads arranged in the peripheral I/O region, which is a peripheral portion of the chip, to a center portion of the chip increases. As a result, the resistance value of an interconnect extending from each power source I/O pad to the center portion of the chip increases, thereby increasing the voltage drop. When the voltage drop increases, a voltage supplied to the inner portion of the chip decreases, which may reduce the working speed.
As a technique related to improving the capacity to supply power to the inner portion of the chip, a flip-chip package is used.
With the flip-chip package, the number of signal terminals can be increased, a power source plane can be provided on an intermediate substrate which is referred to as a build-up substrate and connects a package to the chip, and the power source I/O pads can be arranged any positions of the inner portion of the chip, so that it is possible to improve the capacity to supply power to the inner portion of the chip.
A plurality of I/O cells 210 and ESD protection circuits 211 are arranged in the peripheral I/O region 201, which is the peripheral portion of the chip 200. The standard cells and macro cells, which are not shown, are arranged in the gate region 202, which is the inner portion of the chip 200, where the standard cells and the macro cells are in the same layer as the plurality of I/O cells 210.
I/O pads 220a, 220b, 221a, 221b, which are illustrated as squares in
The I/O pads 220a, 221b for digital signals are, as illustrated in the figure, connected to, for example, the standard cells in the gate region 202, which is the inner portion of the chip 200, via the I/O cells 210 and interconnects 230. The I/O pads 220b, 221a for analog signals such as power sources are, as illustrated in the figure, connected to the ESD protection circuits 211, and are connected to, for example, the standard cells in the gate region 202, which is the inner portion of the chip 200, via interconnects 230.
Note that
The area I/O pads connected to the power sources are hereinafter referred to as power source area I/O pads, the area I/O pads connected to the signals are hereinafter referred to as signal area I/O pads, the peripheral I/O pads connected to the power sources are hereinafter referred to as power source peripheral I/O pads, and the peripheral I/O pads connected to the signals are hereinafter referred to as signal peripheral I/O pads. When it is not particularly necessary to distinguish these I/O pads from one another, they are simply referred to as area I/O pads, peripheral I/O pads, I/O pads.
Examples of an area I/O pad layout of a flip chip and a power source structure are described, for example, in Japanese Patent Publication No. 2003-068852, Japanese Patent Publication No. 2003-124318, and Japanese Patent Publication No. 2004-047516.
As one of these examples, a conventional area I/O pad layout is illustrated in
Note that there are several types of semiconductor integrated circuit devices depending on their applications, and examples the types are (1) semiconductor integrated circuit devices provided with peripheral I/O pads but without area I/O pads, (2) semiconductor integrated circuit devices provided with peripheral I/O pads and area I/O pads, and (3) semiconductor integrated circuit devices provided with area I/O pads but without peripheral I/O pads.
However, the power source area I/O pad layouts of
The voltage drops in the case of the power source area I/O pad layouts of
The influence of the voltage drop is determined by a drop of a VDD voltage and an increase of a GND voltage. Thus, a resistance from a VDD power source and a resistance from a GND power source are obtained, and the obtained resistances are compared with each other.
First, with reference to
Next, with reference to
In
Likewise, in
Thus, in
[Expression 1]
{(k/(2k+1))+(√2/(2(2+√2)))}R (1)
[Expression 2]
{√2k/(4k+√2))+(1/4)}R (2)
Next, with reference to
In
Likewise, in
Thus, in
[Expression 3]
{(k/(2k+1))+(1/(1+√2))}R (3)
[Expression 4]
{(k/(√2k+1))+(1/3)}R (4)
As described above, in the power source area I/O pad layouts of
A semiconductor integrated circuit device of the present invention was devised to solve the problems discussed above. The detailed description describes implementations of a layout of area I/O pads and power source area I/O pads which differs between the center portion and the peripheral portion of the gate region of the chip so that the voltage drop depending on positions in the gate region is reduced.
Specifically, an example semiconductor integrated circuit device of the present invention includes: a peripheral I/O region in which I/O cells are arranged; a gate region surrounded by the peripheral I/O region; a plurality of area I/O pads arranged in the gate region; and at least first and second power sources, wherein the plurality of area I/O pads include area I/O pads connected to the first power source, and area I/O pads connected to the second power source, and arrangement relationship among the area I/O pads connected to the first power source and the area I/O pads connected to the second power source differs between a center portion and a peripheral portion of the gate region.
In the example semiconductor integrated circuit device of the present invention, the area I/O pads connected to the first power source and the area I/O pads connected to the second power source are alternately arranged only in a row direction or only in a column direction in the center portion of the gate region.
In the example semiconductor integrated circuit device of the present invention, the area I/O pads connected to the first power source and the area I/O pads connected to the second power source are alternately arranged both in a row direction and in a column direction in the peripheral portion of the gate region.
In the example semiconductor integrated circuit device of the present invention, the area I/O pads connected to the first power source and the area I/O pads connected to the second power source are alternately arranged, in at least two rows or two columns, both in a row direction and in a column direction in the peripheral portion of the gate region.
In the example semiconductor integrated circuit device of the present invention, the first power source is a high-voltage power source, and the second power source is a ground power source.
In the example semiconductor integrated circuit device of the present invention, the plurality of area I/O pads include area I/O pads connected to a third power source, and arrangement relationship among the area I/O pads connected to the first power source, the area I/O pads connected to the second power source, and the area I/O pads connected to the third power source differs between the peripheral portion and the center portion of the gate region.
In the example semiconductor integrated circuit device of the present invention, the area I/O pads connected to the third power source are provided in either one of the center portion or the peripheral portion of the gate region.
In the example semiconductor integrated circuit device of the present invention further includes: a plurality of peripheral I/O pads arranged in the peripheral I/O region.
Thus, in the present invention, the layout of the power source area I/O pads differs between the center portion and the peripheral portion of the gate region of the chip. For example, the layout of the power source area I/O pads differs between the center portion and the peripheral portion of the gate region of the chip such that the area I/O pad layout of
As described above, the semiconductor integrated circuit device of the present invention has a layout of the power source area I/O pads which differs between the center portion and the peripheral portion of the gate region of the chip, so that it is possible to prevent locally-increased voltage drops on the chip.
A first embodiment of the present invention will be described below with reference to the drawings.
A power source area I/O pad layout illustrated in
With this power source area I/O pad layout, as also described above, the area I/O pad layout of
Although the peripheral portion P of the gate region G in the example of
A second embodiment of the present invention will be described below with reference to the drawings.
A power source area I/O pad layout illustrated in
As illustrated in the figure, in three columns and three rows in a peripheral portion P of a gate region G of a chip 101, different power source area I/O pads are sequentially aligned both in a row direction and in a column direction. That is, both in the row direction and in the column direction, the VDD1 area I/O pads 1101, the VDD2 area I/O pads 1102, and the GND area I/O pads 104 are alternately aligned. Moreover, a layout in a center portion M of the gate region G of the chip 101, that is, in portions of the gate region G except for the peripheral portion P is such that the same power source area I/O pads are aligned in the row direction, and different power source area I/O pads are sequentially aligned in the column direction. That is, the VDD1 area I/O pads 1101, the VDD2 area I/O pads 1102, or the GND area I/O pads 104 are successively aligned in the row direction, and the VDD1 area I/O pads 1101, the VDD2 area I/O pads 1102, and the GND area I/O pads 104 are sequentially aligned in the column direction.
With this power source area I/O pad layout, in the same manner as in the first embodiment, the voltage drops can be reduced both in the center portion M and the peripheral portion P of the gate region G.
Although the peripheral portion P of the gate region G in the example of
A third embodiment of the present invention will be described below with reference to the drawings.
A power source area I/O pad layout illustrated in
With this power source area I/O pad layout, in the same manner as in the first embodiment, the voltage drops across both the center portion M and the peripheral portion P of the gate region G can be reduced.
The present embodiment is different from the second embodiment in that the VDD2 area I/O pads 1102 are provided only in the peripheral portion P of the gate region G of the chip 101. For example, in the case where blocks to which power is supplied via the VDD2 area I/O pads 1102 are provided only at the periphery of the gate region G, the VDD2 area I/O pads 1102 are arranged only in the peripheral portion P of the gate region G, so that the number of VDD1 area I/O pads 1101 arranged in the center portion M of the gate region G increases, thereby optimally reducing the voltage drop as a whole. Note that the layout is not limited to the example of the present embodiment. In the case where blocks to which power is supplied via the VDD2 area I/O pads 1102 are provided only in the center portion of the gate region G, a layout which is a reversal of the above-described layout may be used.
Although the peripheral portion P of the gate region G in the example of
A fourth embodiment of the present invention will be described below with reference to the drawings.
The layout of the power source peripheral I/O pads illustrated in
With this power source area I/O pad layout, in the same manner as in the first embodiment, the power source layout of
Although the peripheral portion P of the gate region G of the example of
In the present embodiment, there are two types of the power source peripheral I/O pads and the power source area I/O pads which are connected to the high-voltage power source VDD and the ground power source GND, but even when three or more types thereof are provided, the same advantages can, of course, be obtained when they are arranged as in the second embodiment, or in the third embodiment.
As described above, in the semiconductor integrated circuit device of the present invention, the layout of the power source area I/O pads differs between the center portion of the gate region of the chip and the peripheral portion of the gate region of the chip, so that voltage drops across any positions of the gate region of the chip can effectively be reduced, which can alleviate the performance degradation of the chip. Thus, the semiconductor integrated circuit device of the present invention is useful in designing semiconductor integrated circuit devices having power source area I/O pads.
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